This module is a variation on the Serge Voltage Variable Q VCF module (VCFQ) and the Extended Range VCF (VCFX).

From the 1982 Serge catalog:

The VARIABLE Q VCF (VCFQ) is an excellent general-purpose VCF offering
simultaneous low-pass, high-pass, band-pass and notch (band-reject) outputs.
The resonance (Q) of this filter is dynamically variable by manual or
voltage control. The VCFQ has two signal inputs. One incorporates an
automatic gain control to prevent the filter from overloading at high Q
settings. The second input has a level control so that the percussive
effects of overloading the filter can be exploited. When a pulse is applied
to the Trigger input, the filter will ring, producing a damped waveform
similar to that produced by striking a resonant object. The nature of this
ringing is controlled by the Q and the filter frequency. Percussive effects
ranging from clicks to the sound of wood blocks and bell tones can be
produced and controlled. This ringing effect can be used in conjunction with
signals applied to either of the audio inputs to achieve highly controlled
complex tonal qualities.

In addition to the three VCF's, Serge Modular offers an EXTENDED RANGE VCF
(VCFX) which is identical to the VCFQ except it features a second sub-audio
range. This low-frequency range allows use as a control voltage processor. A
fast envelope or trigger applied to the filter in the low range at high Q
settings will cause low-frequency ringing, generating complex envelopes and
damped vibrato effects. The VCFX can be patch programmed to oscillate by
patching the band-pass output to the manual input. The outputs will be in
quadrature relationships (90 degrees out of phase).

A little on how it works:

The schematic for Serge Voltage Variable Q VCF module.

Construction

The CGS112 VCFQ uses three CGS108 Serge Gain Cells as it's voltage controlled elements. Refer to the CGS108 page for construction details. The boards are built exactly as per that page. They should be the last things you install on the CGS112 PCB.

Before you start assembly, check the board for etching faults. Look for any shorts between tracks, or open circuits due to over etching. Take this opportunity to sand the edges of the board if needed, removing any splinters or rough edges.

When you are happy with the printed circuit board, construction can proceed as normal, starting with low profile components such as resistors and diodes first, followed by successively taller components.

Take particular care with the orientation of the polarized components, such as ICs, electrolytics, diodes, and transistors.

When inserting the ICs in their sockets, if used, take care not to accidentally bend any of the pins under the chip. Also, make sure the notch on the chip is aligned with the notch marked on the PCB overlay.

R12: This resistor is not usually fitted. If a 100k is soldered in this position, the frequency controls will also affect the Q.
CX, CY, CZ: Stabilizing capacitors. If you find you have high frequency oscillation occurring in your op-amps, fit 33pF - 47pF capacitors in these positions.

The 1M resistor connected to pad R is incorrectly marked. It should be 100k.

The first time you power it up, I would suggest you do so with 22 ohm resistors in series with the positive and negative power rails. This should save the chips if you have made a blunder.

PAD ID

Function

A

to Q pot wiper

B

to Trigger input jack

C

0V for pots. CCW end of Q pot. CW end of FREQ pot

D

Unused 1V/oct input

E

1V/oct input

F

to Frequency pot wiper

G

to CW end of VC F pot

H

to CCW end of VC F pot

Wiper of VC F pot goes to VC C jack via a 47k resistor physically mounted between the two (i.e. use a 47k resistor as the wire between them)

I

VCQ input

J

High pass out

K

Notch out (called AGC Out on older panels)

L

Band pass out

M

To wiper on Gain pot. (Input on old VCFX)

N

+12V power for pots. CW end of Q pot. CCW end of FREQ pot

P

Range switch pole 1 end

P'

Range switch pole 1 common

R

AGC IN

S

Range switch pole 2 end

S'

Range switch pole 2 common

T

Low pass out

W

0V power connection (not used)

X

+12V power connection (not used)

Z

-12V power connection (not used)

Set Up

The only trim pot on the CGS112 PCB is adjusted to give a 1 volt per octave response. See the VCO page for suggestions on how to set this. It is probably easier to adjust while the filter is set to self oscillation (Patch IN 2 to BP output, and turn up GAIN pot).

From Serge kit instructions:

Test Procedure;

1. Apply a sawtooth wave from an oscillator or slew into input 1. Manually turning the center frequency pot and the "Q" pot should produce filter sweeps of varying "Q"s and frequency ranges at the LOW, HIGH, and BAND pass outputs.

2. Using a control voltage source, test the VC-F and VC-Q functions. Note the processing input on the VC-F as well as a calibrated IV/octave input.

3. Apply a signal to the manual gain input (IN 2), and turn up the manual gain pot. This input differs from IN 1 in that the gain of IN 1 is automatically controlled for use with increasing Q. As Q is increased, the gain of IN I is decreased to compensate for the peaked response of the high Q filter. Note the difference by first applying a signal to IN 2 and increasing and decreasing the Q, then applying a signal to IN 1 varying the Q.

4. The NOTCH output should produce a phasing type sound if a sawtooth wave or a noise signal is applied to the filter input, the 0 is low, and the frequency is swept.

5. Apply a pulse source into the TRIG input while listening to the BAND output. A percussive timbre should be present which can be changed dramatically by changing the filter frequency and increasing the Q.